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Consider a std::vector v of N elements, and consider that the n first elements have already been sorted withn < N and where (N-n)/N is very small:

sorted/unsorted vector

Is there a clever way using the STL algorithms to sort this vector more rapidly than with a complete std::sort(std::begin(v), std::end(v)) ?

EDIT: a clarification: the (N-n) unsorted elements should be inserted at the right position within the n first elements already sorted.

EDIT2: bonus question: and how to find n ? (which corresponds to the first unsorted element)

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The answer to EDIT2 is std::is_sorted_until – Blastfurnace Feb 6 '14 at 1:44
Is doing it in-place a requirement? It seems to be implied, but you do not say it explicitly. – AnT Feb 6 '14 at 2:05
If N-m is small, then you can use insertion sort. Yes, it is considered as a bad sorting algorithm, but the fact is that it is efficient when the input is almost sorted. Alternatively if you can spare a bit of extra memory, you can move the unsorted elements into a different vector, sort it and do a merge sort, in which case you might want to sort from the end rather than the beginning. – David Rodríguez - dribeas Feb 6 '14 at 3:43
What's the problem with std::sort? You don't have to provide the iterator to the starting element. You might as well provide iterator to 200th element (as in vec.begin() + 199) – W.B. Feb 6 '14 at 8:27
C++ stdlib doesn't has some adaptive sorting algorithms available? (e.g. timsort) Otherwise you could just use those to sort the whole array and the algorithm would automatically avoid to waste time in the first part. – Bakuriu Feb 6 '14 at 9:31

7 Answers 7

up vote 21 down vote accepted
void foo( std::vector<int> & tab, int n ) {
     std::sort( begin(tab)+n, end(tab));
     std::inplace_merge(begin(tab), begin(tab)+n, end(tab));

for edit 2

auto it = std::adjacent_find(begin(tab), end(tab),  std::greater<int>() );
if (it!=end(tab)) {
    std::sort( it, end(tab));
    std::inplace_merge(begin(tab), it, end(tab));
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I added a question (see EDIT 2) – Vincent Feb 6 '14 at 1:42
@Vincent you should open a new question then, anyway, here your answer for this time – galop1n Feb 6 '14 at 1:48
You could use std::is_sorted_until instead of that std::adjacent_find – Blastfurnace Feb 6 '14 at 1:48
Again, standard inplace_merge is formally a "fake", "simulated" in-place merge. The standard allows it to work out-of-place and allows it to perform a full sort. Frankly, I don't remember ever seeing a single honest implementation that is in-place and is not a full sort. The algorithm is too complicated to bother. If you know one, please tell me. – AnT Feb 6 '14 at 2:10

Sort the other range only, and then use std::merge.

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merge need separated input and output, the correct algorithm to use is inplace_merge here. – galop1n Feb 6 '14 at 1:41
I know, but the OP didn't tell if he wanted to have it in place. – Kornel Kisielewicz Feb 6 '14 at 2:33
While your post is not a classical case of link-only answer, because it contains at least a name of a function, that's still only a bit above the threashold. Please provide at least a minimalistic usage example, at best connected with OPs problem. I know this was upvoted by many people, but would they upvote too, if the link was removed? – Danubian Sailor Feb 12 '14 at 8:16

The optimal solution would be to sort the tail portion independently and then perform in-place merge, as described here

The algorithm is quite convoluted and is usually regarded as "not worth the effort".

Of course, with C++ you can use readily available std::inplace_merge. However, the name of that algorithm is highly misleading. Firstly, there's no guarantee that std::inplace_merge actually works in-place. And when it is actually in-place, there's no guarantee that it is not implemented as a full-blown sort. In practice it boils down to trying it and seeing whether it is good enough for your purposes.

But if you really want to make it in-place and formally more efficient than a full sort, then you will have to implement it manually. STL might help with a few utility algorithms, but it does not offer any solid solutions of "just a few calls to standard functions" kind.

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From the complexity bounds given in the Standard, it seems that a conforming inplace_merge is not even allowed to use the optimal algorithm, which is considerably more expensive than the naive approach in terms of comparisons performed. But then of course the naive approach requires allocation of a temporary buffer. – ComicSansMS Feb 6 '14 at 16:57

Using insertion sort on N - n last elements:

template <typename IT>
void mysort(IT begin, IT end) {
    for (IT it = std::is_sorted_until(begin, end); it != end; ++it) {
        IT insertPos = std::lower_bound(begin, it, *it);
        IT endRotate = it;
        std::rotate(insertPos, it, ++endRotate);
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The Timsort sorting algorithm is a hybrid algorithm developed by Pythonista Tim Peters. It makes optimal use of already-sorted subsegments anywhere inside the array, including in the beginning. Although you may find a faster algorithm if you know for sure that in particular the first n elements are already sorted, this algorithm should be useful for the overall class of problems involved. Wikipedia describes it as:

The algorithm finds subsets of the data that are already ordered, and uses that knowledge to sort the remainder more efficiently.

In Tim Peters' own words,

It has supernatural performance on many kinds of partially ordered arrays (less than lg(N!) comparisons needed, and as few as N-1), yet as fast as Python's previous highly tuned samplesort hybrid on random arrays.

Full details are described in this undated text document by Tim Peters. The examples are in Python, but Python should be quite readable even to people not familiar with its syntax.

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Use std::partition_point (or is_sorted_until) to find n. Then if n-m is small do an insertion sort (linear search+std::rotate).

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It is expected to elaborate a bit more on SO. Please provide at least single-line use example, at best so that it would pass to OPs code. – Danubian Sailor Feb 12 '14 at 8:17

I assume that your question has two aims:

  • improve runtime (using a clever way)
  • with few effort (restricting to STL)

Considering these aims, I'd strongly recommend against this specific optimization, unless you are sure that the effort is worth the benefit. As far as I remember, std::sort() implements the quick sort algorithm, which is almost as fast on presorted input as to determine, if / how-much-of the input is sorted.

Instead of meddling with std::sort you can try changing the data structure to a sorted/prioritized queue.

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Quicksort is not fast on pre-sorted input. It may be very slow, for certain choices of pivot (unlikely in modern implementations), but the best-case performance of quicksort is O(n log n). – Sneftel Feb 6 '14 at 12:32
You're right. In fact, I messed up: Sorted data can be the worst case for quicksort (depending on an unlikely choice of pivot). However, if the data is always sorted but for the last few appended elements, there is no need to check the first elements. You can simply have the data structure sort the last elements, when appending them. In this I assume that the vector is build up successively, because that's how a situation like this typically occurs. – No answer Feb 6 '14 at 17:20

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